RU39328U1 - BIOCHEMICAL WASTE WATER TREATMENT PLANT - Google Patents

Abstract

Essence: the installation contains a primary clarifier, an aeration tank, a secondary clarifier, a biofilter with loading, a tertiary clarifier and a sludge stabilizer. Loading is made in the form of flat carriers of biomass, collected in a package and fixed on a rigid base. The gaps between the biomass carriers on the sides of the package are covered with solid partitions, with even gaps on one side of the package overlapping and odd gaps on the other. Purpose: increasing the degree of purification.

Description

The utility model relates to wastewater treatment and can be used in the treatment of industrial and domestic wastewater.

A known installation for biochemical wastewater treatment, containing a primary sump, a loading biofilter in the housing of which an aerator is located, as well as a tertiary sump.

(USSR author's certificate No. 1641780, IPC ⁷ C 02 F 3/00, 1988).

Such an installation does not provide a high degree of wastewater treatment.

The closest in technical essence and the achieved result is the installation for biochemical wastewater treatment

water containing primary, sump, aeration tank, secondary sump, loading biofilter, in the housing of which there is an aerator comprising a perforated frame tube and a dispersing element made of finely porous material, as well as a tertiary sump (RF Patent Utility Model No. 33373, IPC ⁷ C 02 F 3/02, 06.16.2003).

However, this installation also does not provide a sufficiently high degree of wastewater treatment.

The task to which the utility model is directed is to increase the degree of wastewater treatment.

The problem is solved in that in a plant for biochemical treatment of wastewater containing a series-connected primary sump, aeration tank, a secondary sump, a loading biofilter, in the casing of which there is an aeration pipe including a perforated frame tube and a dispersing element made of finely porous material, as well as tertiary sump biofilter loading completed

in the form of flat biomass carriers collected in a bag and fixed on a rigid base, the gaps between the biomass carriers on the sides of the bag are covered with solid partitions, even odors are blocked on one side of the bag and odd on the other, and the dispersing element of the biofilter aerator can be made in the form of a tubular shell located on the outer surface of the perforated frame pipe, or in the form of a disk located on the frame pipe from the loading side. The pore size of the material of the dispersing element is preferably in the range of 50-150 microns.

Figure 1 presents a diagram of the installation for biochemical wastewater treatment, General view; figure 2 - installation biofilter, side view on an enlarged scale; figure 3 is a section aa in figure 2.

Installation for biochemical wastewater treatment, contains a pipeline 1 for supplying untreated wastewater, a primary sump 2 with an airlift installed in it 3. In the partition 4 there is an overflow threshold 5. Behind the primary sump 2 there is an aeration tank 6 with the installed author 7. Through an overflow partition 8, the aeration tank 6 is connected to the secondary clarifier 9, in which the airlifts 10 and 11 are installed. Through the overflow partition 12, the secondary clarifier 9 is connected to the biofilter 13, in the casing 14 of which cassette loading 16 is installed on the racks 15, and also located, the aerator 17. The aerator 17 contains a perforated frame tube 18 with a dispersing shell 19 located on its outer surface and made of finely porous material with a pore size in the range of 50-150 microns.

The load 16 contains a carrier base 20, made in the form of a rigid frame of corners 21 with a mesh fixed to them

22. On the outer surface of the corners 21 of the base 20 there are also sections of the mesh 22, on each side of the load 16, the corners 21 are installed with a gap between them equal to the width of the corner shelf, while in the plan the corners 21 of one side of the load 16 correspond to the gaps of the other side. Formed in this way, the openings 23 have a pocket shape in plan. To increase the rigidity of the design of the boot 16 there is a jumper 24.

On the side of the rear wall of the casing 14, a tertiary sump 25 is adjacent to the biofilter, inside of which, airlifts 26 and 27 are installed. In the sump 25 there is an outlet tray 28 for purified water, a sludge stabilizer 29 is installed behind the tertiary sump 25, inside which there is an aerator 30 and airlift 31. Airlifts and aerators of the installation are connected to the air line 32. There is a pipe 33 for the release of treated water, and a pipe 34 for the discharge of waste sludge.

Installation for wastewater treatment is as follows.

The source wastewater through pipeline 1 enters the primary sump 2. The sludge from the primary sump 2 is removed by airlift 3 into the sludge stabilizer 29 as it accumulates.

After preliminary treatment in the sump 2, water through the overflow threshold 5 of the partition 4 enters the aeration tank 6, where it is subjected to the first stage of biological treatment with suspended activated sludge. Using an aerator 7 in the aeration tank 6 provides the flow of the aerobic process.

After aeration tank 6, water suspended sludge through the partition 8 enter the secondary sump 9, where the separation of the sludge mixture takes place. Excess activated sludge is removed from the bottom, sedimentation tank 9 airlift 10 stabilizer 29 sludge. To maintain not

the required dose of sludge in aeration tank 6 airlift 11 pumps part of the settled sludge through the recirculation line into the volume of aeration tank 6. In this scheme, a set of microorganisms develops in suspended sludge, which intensively purify wastewater with a high initial concentration of pollution.

Water after the secondary sump 9 through the baffle 12 enters the biofilter 13 submersible type. The second stage of aerobic cleaning is carried out in it thanks to the supply of atmospheric air oxygen through the aerator 17. When air passes through the perforated frame tube 18 and the dispersing element 19, air bubbles are formed with a size of 0.3-2.5 mm in diameter, which corresponds to the range of fine bubble aeration.

During aeration, the biofilm grows on the mesh bio-carrier 22. The location of the grid 22 in the form of a flat spiral with small gaps between the turns contributes to the engagement on the biofilm and the growth of colonies of filamentous bacteria in the internal volumes of the pockets. 23. These bacteria are highly effective in wastewater treatment, but they form in the conditions of ordinary aeration tanks “swollen” or, disrupting their work. Under the regime of soft bubbling from the fine bubble aerator 17, the colonies of filamentous bacteria remain in a fixed state and do not form a “swollen” sludge

In the process of development, part of the biofilm from the outer layers is separated and removed with water through the upper edge of the wall of the housing 14 of the biofilter 13 into the tertiary settler 25. Excess biofilm is removed from the bottom of the settler 25 by airlift 26 into the sludge stabilizer 29. Part of the settled biofilm with airlift 27 is returned to the biofilter 13 and re-participates in the cleaning process in suspension, which contributes to a deeper water purification.

Apart from the aeration tank 6, the biofilter 13 recirculation system ensures the development of its own set of microorganisms adapted to process the remaining pollutants in the water at their low concentration.

After the tertiary sump 25, the purified water through the outlet tray 28 and the pipe 33 is removed from the installation.

When air is supplied through the aerator 30, the sludge is mineralized in the sludge stabilizer 29. At the end of the stabilization cycle, the mineralized sludge and the processed sludge from the primary settling tank 2 are removed from the sludge stabilizer 29 by an airlift 31 through the sludge 34, the General air supply to ensure the operation of aerators and airlifts is carried out through the duct 32.

Thus, the separation of biomass in the installation into a suspended id and a biofilm with fixed colonies of filamentous bacteria under fine bubble aeration with independent recirculation systems can significantly increase the efficiency of wastewater treatment.

Claims (5)

1. Installation for biochemical wastewater treatment, containing serially connected primary sump, aeration tank, secondary sump, loading biofilter, in the housing of which there is an aerator comprising a perforated frame pipe and a dispersing element made of finely porous material, as well as a tertiary sump, characterized in that the loading of the biofilter is made in the form of flat biomass carriers collected in a package and fixed on a rigid base. 2. Installation according to claim 1, characterized in that the spaces between the biomass carriers of the filter are blocked by solid partitions on the sides of the bag, and even odors are blocked on one side of the bag, and odd on the other. 3. Installation according to claim 1, characterized in that the dispersing element of the biofilter aerator is made in the form of a tubular shell located on the outer surface of the perforated frame pipe. 4. Installation according to claim 1, characterized in that the dispersing element of the biofilter aerator is made in the form of a disk located on the frame pipe from the loading side. 5. Installation according to claim 1, characterized in that the pore size of the material of the dispersing element is in the range of 50-150 microns.